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䡵 Interferon Therapy Basis and Clinical Applications of Interferon JMAJ 47(1): 7–12, 2004 Jiro IMANISHI Professor, Kyoto Prefectural University of Medicine Abstract: Interferon (IFN) is an antiviral substance that was discovered about 50 years ago. The advance in the basic research of IFN has revealed the action mechanism of its antiviral effect at a molecular level and provided wide clinical applications. It is roughly divided into 3 types: IFN-␣, IFN-, and IFN-␥. IFN-␣ is related to IFN-, but IFN-␥ is completely different. Any type of IFN is a (glyco) protein with a molecular weight of about 20,000kDa. IFN is known to have various biological activities including antiviral effects. Major biological activities include cell growth inhibition and immune regulation. Anti-tumor effect of IFN develops by integration of the various biological activities. IFN is considered to exert its antiviral effect by not only directly inhibiting viral proliferation, but also stimulating cytotoxic T cells, natural killer cells, and macrophages. Key words: Interferon; Inhibition of viral proliferation; Immunomodulating effect; NK cell; Helper T cell Introduction Types and Properties Interferon was first discovered by Nagano and Kojima1) in Japan as a virus inhibiting factor in 1954. It was also discovered by Isaacs and Lindenmann2) in 1957 as a substance responsible for virus interference. About a half century has passed since its discovery. It has been clinically applied to treat various diseases for more than 20 years. This paper outlines interferon and explains the results of the basic research toward its clinical application. Interferon (IFN) is generally classified into 3 types (Table 1). First, IFN-␣ is produced when leukocytes are infected with a virus. It is also called leukocyte interferon. Second, IFN- is produced when fibroblasts are infected with a virus or treated with synthetic double-stranded RNA (polyinosinic acid/polycytidylic acid complex; poly I :C). It is also called fibroblast interferon. Third, IFN-␥ is produced when lymphocytes are stimulated with a mitogen or sensitized lymphocytes are bound to an antigen. It is also called immune interferon. This article is a revised English version of a paper originally published in the Journal of the Japan Medical Association (Vol. 128, No. 7, 2002, pages 1013–1017). JMAJ, January 2004—Vol. 47, No. 1 7 J. IMANISHI Table 1 Types and Properties of Human (Hu) IFN Type I Type II HuIFN-␣ Molecular weight No. of amino acids No. of genes Subtype HuIFN- HuIFN-␥ About 20,000 About 20,000 About 20,000 (monomer) About 40,000 (dimer) 165–166 172 166 146 23 or higher (including 4 pseudogenes) About 7 (including 6 pseudogenes) 1 1 14 or higher 1 1 1 0 0 0 3 9p21 9p21 9p21 12q24.1 No Yes Yes Yes ␣ ␣  ␥ Leukocyte Trophoblast Fibroblast Th1⬍NK Type I (common to ␣,  and ) Type I (common to ␣,  and ) Type I (common to ␣,  and ) Type II (specific to ␥ ) 21q22.1 21q22.1 21q22.1 6q16-q12 Weak Weak Weak Strong Normal HuIFN- HuIFN- About 20,000 Intron Gene location Presence/absence of sugar chain Antigenic type Main producer cell Receptor Receptor gene location Species specificity IFN-␣ is similar to IFN- because both have 166 amino acids (some types of IFN-␣ have 165 amino acids) and because there is about 50% homology for their amino acid sequences, or the nucleotide sequences that code them. Furthermore, since the genes for IFN-␣ are located at the same chromosome as that for IFN- (9p21 for humans), IFN-␣ is genetically related to IFN-. It has been revealed that IFN-␣ has 14 or more subtypes, and that there are 23 or more genes for IFN-␣ including pseudogenes. In contrast, IFN- has one gene and one subtype. IFN-, a subtype of IFN-␣, has 172 amino acids. The genes for IFN- are also located at the same chromosome and there is 60% or higher homology for amino acid and nucleotide sequences.3) Another type of IFN is produced from pla- 8 JMAJ, January 2004—Vol. 47, No. 1 cental trophoblasts and called trophoblast IFN. This type of IFN is also called IFN-. It is considered to be closely related to the recognition of pregnancy by the parent body.4) One recent development is a form of consensus IFN-␣ that has a structure common to the subtypes of IFN-␣. The consensus IFN-␣ is considered to provide higher efficacy than normal IFN-␣, with fewer adverse effects. IFN-␥ usually exists as a dimer and has 146 amino acids, 20 fewer amino acid as compared with the 166 amino acids of IFN-␣ or IFN-. It has one gene located at the chromosome of 12q24.1 for humans. These facts indicate that IFN-␥ is completely different from IFN-␣ or IFN-. BASIS AND CLINICAL APPLICATIONS OF INTERFERON Table 2 Various Biological Activities of IFN 1. Anti-tumor effect 2. Inhibitory effect on cell growth 3. Effects on lymphocytes a) Stimulation and inhibition of antibody production (B cell) b) Inhibition of delayed-type hypersensitivity (T cell) c) Inhibition of transplantation immune response (T cell) d) Inhibition of blastogenesis and DNA synthesis (T cell) e) Potentiation of killer T cells (T cell) f ) Potentiation of natural killer activity (NK cell) g) Potentiation of ADCC activity 4. Effects on macrophages a) Potentiation of phagocytosis b) Potentiation of adherence to tumor cells c) Inhibition of intracellular bacterial proliferation d) MIF activity e) Chemotaxis 5. Other effects on cells a) Chemotaxis for neutrophils b) Potentiation of NBT reduction in neutrophils c) Increased histamine release in basophils d) Promotion of differentiation of erythroblasts e) Induction of differentiation of neuroblastoma cells f ) Potentiation of expression of MHC Class I and II antigens Biological Activity Many of the various biological activities of IFN are known and understood (Table 2). Naturally enough, since it was first discovered as an antiviral agent, we know that it engages in antiviral activity (inhibits viral proliferation). Other known activities include inhibition of cell growth and effects on immunological activity. In general, IFN stimulates macrophage and natural killer (NK) activities and plays important roles in host defense. IFN, particularly IFN-␥, plays a key part in regulating the biological immune response, as described below. It is also considered that IFN exerts its effects on viral infection and malignant tumors, as described in the following sections, by combining all of its diverse biological activities. 1. Antiviral activity The mechanism of antiviral activity of IFN (inhibition of viral proliferation) has been generally revealed (Fig. 1). The binding of the IFN molecule to its receptor activates two enzymatic systems. One is the 2-5A synthetase system (2-5A oligosynthetase). When the enzyme is activated, 2-5A is synthesized in the presence of ATP and double-stranded RNA. 2-5A activates endo-RNase (endonuclease) to degrade viral mRNA, thereby inhibiting viral protein synthesis. The other enzymatic system is protein kinase (PKR), which is also activated in the presence of double-stranded RNA. When activated, it phosphorylates the initiation factor-2␣ (eIF2␣) required for starting the synthesis of peptide chains on ribosomes, thereby inactivating eIF-2␣. This prevents the virus from commencing protein synthesis on the ribosome, and results in the inhibition of viral proliferation. In addition to the two enzymatic systems responsible for the inhibition of viral proliferation, other known mechanisms include the inhibition of transcription into viral mRNA and viral inhibition at the viral particle budding phase. It is considered that appropriate action JMAJ, January 2004—Vol. 47, No. 1 9 J. IMANISHI IFN A T P: adenosine triphosphate AMP: adenosine monophosphate IFN receptor � 2⬘-5⬘ oligosynthetase (2-5AS) system Inactive 2-5AS Active 2-5AS Inactive endo-RNase ATP 2-5A Double-stranded RNA Active endo-RNase Degradation of viral mRNA Phosphodiesterase AMP � Protein kinase (PKR) system Inactive PKR elF-2움 Phosphatase Active PKR Inhibition of the start of viral peptide chain synthesis Phosphorylated elF-2움 Double-stranded RNA Fig. 1 Mechanism of antiviral effect of IFN Th1 IFN-웂, IL2 TNF-웁 Cellular immunity IL2, IL12 IL2, IFN-웂 IFN-g Thp IFN-웂 IFN-g IL4, IL10 Tho IL4, TNF-웁 IL2, IL4 Th2 IL4, 5, 6, 10 Humoral immunity Fig. 2 Th1 and Th2 cytokine mechanisms of IFN may function depending on viral type. 2. Effects on the immune system IFN has been known to have many effects on the immune system. It is considered to generally inhibit antibody production and delayedtype (Type IV) hypersensitivity. However, it stimulates cytotoxic T cells (killer T cells), NK 10 JMAJ, January 2004—Vol. 47, No. 1 cells, killer cells responsible for antibodydependent cell-mediated cytotoxicity (ADCC), macrophages, and neutrophils. IFN-␥ has a regulatory effect on the immune system: that is, IFN-␥ is produced from type 1 helper T (Th1) cells. It is also known to stimulate the growth of Th1 cells. Since Th1 cells are involved in cellular immunity, IFN-␥ is considered to increase cellular immunity. In con- BASIS AND CLINICAL APPLICATIONS OF INTERFERON Virus Infection Infected cells Inhibition of viral proliferation Tumor cell destruction Virus-infected cell destruction NK cell Production Infected cells Virus-induced IFN Production Immune IFN Activity potentiation Lymphocyte Killer T cell NK cell K cell Differentiation IFN NK precursor cells Fig. 4 Re-infection and recurrence IFN-NK system Macrophage Healing Fig. 3 Antiviral effect of IFN trast, since IFN-␥ suppresses the activity of Th2 cells, it is considered to suppress humoral immunity (Fig. 2). Effects on Viral Infections For the action mechanisms of IFN on viral infections, IFN directly provides antiviral effects and indirectly inhibits viral infections through the immune system (Fig. 3). IFN enhances the activities of macrophages, NK, and ADCC to inhibit viral proliferation in infected cells and destroy infected cells. It is considered that the same mechanisms work for tumors. IFN directly inhibits the proliferation of tumor cells, and generally has a stronger growth inhibitory effect on tumor cells than on normal cells. IFN is also known to induce apoptosis in some cells. Thus, IFN not only directly inhibits the proliferation of tumor cells or destroys them, but also indirectly inhibits them by stimulating the immune system. As described above, IFN is known to enhance the activity of killer T cells, NK cells, and ADCC, and to stimulate macrophages and neutrophils to destroy tumor cells. IFN is known to form a cycle with NK cells. That is, IFN increases NK activity, activated NK cells produce IFN, and IFN acts on NK precursor cells to induce the differentiation of NK cells, thereby increasing NK cells. This system formed by IFN and NK cells is called IFNNK system (Fig. 4). The IFN-NK system is deeply involved in host defense against viral infection and against tumors. It is well known that the IFN-NK system strongly inhibits tumor metastasis. Conclusions IFN engages in various biological activities including antiviral action. It combines all its activities to provide protection against viral infections and tumors. It is important to clinically apply IFN by managing both the direct and indirect effects of IFN. REFERENCES 1) 2) Nagano, Y. and Kojima, Y.: Pouvoir immunisant de virus vaccinal inactivé par des rayons ultraviolets. C R Soc Biol (Paris) 1954; 148: 1700–1702. Isaacs, A. and Lindenmann, J.: Virus interference. I. The interferon. Proc Roy Soc 1957; B147: 258–267. JMAJ, January 2004—Vol. 47, No. 1 11 J. IMANISHI 3) 12 Capon, D.J., Shepard, H.M. and Goeddel, D.V.: Two distinct families of human and ovine interferon alpha genes are coordinately expressed and encode functional polypeptide. Mol Cell Biol 1985; 5: 768–779. JMAJ, January 2004—Vol. 47, No. 1 4) Pontzer, C.H., Ott, T.L., Bazer, F.W. et al.: Structure/function studies with interferon tau: Evidence for multiple active sites. J Interferon Res 1994; 14 (3): 133–141.